Adsorptive stripping voltammetric determination of nitroimidazole derivative on multiwalled carbon nanotube modified electrodes: influence of size and functionalization of nanotubes

Jara-Ulloa, Paola; Cañete-Rosales, Paulina; Núñez-Vergara, Luis J; Squella, Juan A

doi:10.1590/S0103-50532011000700012

Abstracts

1-Methyl-4-nitro-2-brominemethylimidazole (4-NimMeBr), was electrochemically reduced on mercury, glassy carbon and multiwalled carbon nanotubes (MWCNT) modified electrodes. 4-NimMeBr was adsorbed on the MWCNT modified electrode thus permitting the implementation of an adsorptive stripping voltammetric (ASV) method. We have used 4-NimMeBr as a prototype electroactive nitro compound to study the effect of both the size of the nanotubes and its functionalization by oxidation. The oxidized MWCNT forms better dispersions than the non-oxidized, producing electrode surface with higher density of MWCNT as was determined by electrochemical mapping using scanning electrochemical microscopy (SECM). Under the optimized conditions, the peak current was proportional to the concentration of 4-NimMeBr in the range of 10-6 mol L-1 to 10-4 mol L-1 with detection and quantification limits of 4.41×10-6 mol L-1 and 6.21×10-6 mol L-1, respectively. The sensibility of bare electrode was 0.01 µA per mmol L-1, which was lower than the value of 5.34 and 6.97 µA per mmol L-1 obtained using short and large oxidized MWCNT, respectively.

4-nitroimidazole; carbon nanotubes; adsorptive stripping voltammetry; scanning electrochemical microscopy

1-Metil-4-nitro-2-bromometilimidazol (4-NimMeBr) foi eletroquimicamente reduzido em eletrodos de mercúrio, carbono vítreo e carbono vítreo modificado com nanotubos de carbono de parede múltipla (MWCNT). 4-NimMeBr adsorveu no eletrodo de carbono vítreo modificado com nanotubos de carbono, tornando possível a implementação de um método de quantificação por voltametria de redissolução adsortivo (ASV). 4-NimMeBr foi usado como protótipo de composto eletroativo para estudar o efeito do tamanho dos nanotubos e de sua funcionalização por oxidação, na resposta eletroquímica do eletrodo modificado. Nanotubos oxidados formaram melhores dispersões em água, produzindo uma superfície de eletrodo com alta densidade de MWCNT, como mostram os dados obtidos por microscopia de varredura eletroquímica (SECM). Sob as condições otimizadas, a corrente de pico foi proporcional à concentração de 4-NimMeBr no intervalo de 10-6 mol L-1 a 10-4 mol L-1 com limite de detecção e quantificação de 4,41×10-6 mol L-1 e 6,21×10-6 mol L-1, respectivamente. Além disso, a sensibilidade do eletrodo não modificado com nanotubos foi 0,01 µA per mmol L-1, consideravelmente menor que os valores de 5,34 e 6,97 µA per mmol L-1 obtidos usando nanotubos oxidados de carbono de parede múltipla (pequenos e longos), respectivamente.

ARTICLE

Adsorptive stripping voltammetric determination of nitroimidazole derivative on multiwalled carbon nanotube modified electrodes: influence of size and functionalization of nanotubes

Paola Jara-Ulloa; Paulina Cañete-Rosales; Luis J. Núñez-Vergara; Juan A. Squella^* * e-mail: asquella@ciq.uchile.cl

Bioelectrochemistry Laboratory, Chemical and Pharmaceutical Sciences Faculty, University of Chile, Postal Code 838492 Santiago, Chile

ABSTRACT

1-Methyl-4-nitro-2-brominemethylimidazole (4-NimMeBr), was electrochemically reduced on mercury, glassy carbon and multiwalled carbon nanotubes (MWCNT) modified electrodes. 4-NimMeBr was adsorbed on the MWCNT modified electrode thus permitting the implementation of an adsorptive stripping voltammetric (ASV) method. We have used 4-NimMeBr as a prototype electroactive nitro compound to study the effect of both the size of the nanotubes and its functionalization by oxidation. The oxidized MWCNT forms better dispersions than the non-oxidized, producing electrode surface with higher density of MWCNT as was determined by electrochemical mapping using scanning electrochemical microscopy (SECM). Under the optimized conditions, the peak current was proportional to the concentration of 4-NimMeBr in the range of 10^-6 mol L^-1 to 10^-4 mol L^-1 with detection and quantification limits of 4.41×10^-6 mol L^-1 and 6.21×10^-6 mol L^-1, respectively. The sensibility of bare electrode was 0.01 µA per mmol L^-1, which was lower than the value of 5.34 and 6.97 µA per mmol L^-1 obtained using short and large oxidized MWCNT, respectively.

Keywords: 4-nitroimidazole, carbon nanotubes, adsorptive stripping voltammetry, scanning electrochemical microscopy

RESUMO

1-Metil-4-nitro-2-bromometilimidazol (4-NimMeBr) foi eletroquimicamente reduzido em eletrodos de mercúrio, carbono vítreo e carbono vítreo modificado com nanotubos de carbono de parede múltipla (MWCNT). 4-NimMeBr adsorveu no eletrodo de carbono vítreo modificado com nanotubos de carbono, tornando possível a implementação de um método de quantificação por voltametria de redissolução adsortivo (ASV). 4-NimMeBr foi usado como protótipo de composto eletroativo para estudar o efeito do tamanho dos nanotubos e de sua funcionalização por oxidação, na resposta eletroquímica do eletrodo modificado. Nanotubos oxidados formaram melhores dispersões em água, produzindo uma superfície de eletrodo com alta densidade de MWCNT, como mostram os dados obtidos por microscopia de varredura eletroquímica (SECM). Sob as condições otimizadas, a corrente de pico foi proporcional à concentração de 4-NimMeBr no intervalo de 10^-6 mol L^-1 a 10^-4 mol L^-1 com limite de detecção e quantificação de 4,41×10^-6 mol L^-1 e 6,21×10^-6 mol L^-1, respectivamente. Além disso, a sensibilidade do eletrodo não modificado com nanotubos foi 0,01 µA per mmol L^-1, consideravelmente menor que os valores de 5,34 e 6,97 µA per mmol L^-1 obtidos usando nanotubos oxidados de carbono de parede múltipla (pequenos e longos), respectivamente.

Introduction

The study of the electrochemistry of nitro compounds began early in 1900, when Haber¹ revealed the stepwise reduction of nitrobenzene, but there is still a great interest in this type of compounds. One reason for such interest is that numerous nitro compounds are manufactured for use as pharmaceuticals and consequently they are introduced into living organisms and metabolized often via redox type processes. Compounds with the most extensive clinical application in this capacity are nitroimidazoles that have been employed in the treatment of anaerobic infections and in cancer treatment as hypoxic cell cytotoxins and radiation sensitizers.^2,3 Due to his pharmacological activities, the synthesis of new nitroimidazole compounds remains as a very active area of research.^4-6 It is a well known matter that the biological activity of nitroimidazole compounds is related to the redox chemistry of the nitro group.⁷ This aspect has motivated a great number of electrochemical studies and consequently, the redox chemistry of different nitro compounds of biological significance is focused to understand how the reduction of the nitro group can play an active role in several aspects as: electroanalytical determinations, free radical generation, stability and reactivity.⁸

From the electroanalytical point of view the most useful signal for quantitative purposes is the four electron four-proton signal due to the reduction of the nitro group to produce the hydroxylamine derivative. The advantages of this signal are both the high quantity of current produced per mol of electroactive compound and the relative low energy requirements for the nitro reduction. Therefore we can obtain high current/concentration ratios and low reduction potentials. These advantages have permitted the development of a great quantity of electrochemical methods applied to nitroimidazole derivatives using different techniques such as: cyclic voltammetry,^9,10 square wave adsorptive stripping voltammetry,¹¹ cathodic adsorptive voltammetry.¹²

On the other hand, the use of multi walled carbon nanotubes (MWCNT) as electrode material has been increasing due to its unique properties, including their remarkable electrical, chemical, mechanical and structural properties.¹³ Furthermore, recently some studies have shown that different types of MWCNT modified electrodes exhibit attractive electrochemical properties producing electrocatalytic effects.^14-16

There are only few papers devoted to applications of carbon nanotubes on nitro compounds. Simple and sensitive electrochemical methods for the detection of ultratrace levels of 2,4,6-trinitrotoluene on glassy carbon electrodes modified with MWCNT has been published.¹⁷ More recently, the electrochemical reduction of nitrophenol isomers at a glassy carbon electrode modified with MWCNT,¹⁸ the electrochemical reduction of nitrobenzene at MWCNT electrode,¹⁹ and the voltammetric reduction of a 4-nitroimidazole derivative on a multiwalled MWCNT modified electrode²⁰ have been published. However, none of these studies have reported the effect of size and functionalization of nanotubes in the analytical response of the nitro derivative.

In the present study we have centered our attention on the electrochemical behavior of 4-NimMeBr in order to obtain a voltammetric method to determine it on a MWCNT-modified electrode. Especially we studied the influence of both size of nanotubes and its functionalization by acid oxidation on the analytical determination of this nitro derivative.

Experimental

Reagents and solutions

4-NimMeBr (Figure 1) was synthesized and characterized in our laboratory.

MWCNT 1-5 mm large (short type) or 5-20 mm large (long type) and (30 ± 15) nm diameter were obtained from Nano-Lab (USA). MWCNT were oxidized by chemical treatment with a mixture 3:1 of 3 mol L^-1 H₂SO₄: 3 mol L^-1 HNO₃ by refluxing for 3 h. After that, the suspension was filtered and washed with water until neutral pH. All the other reagents employed were of analytical grade. Nitrogen gas was obtained from AGA Chile S.A. with maximum impurities of H₂O < 3 ppm; O₂ < 2 ppm; C_nH_m < 0.5 ppm.

All the voltammetric experiments were obtained after bubbling with N₂ for 10 min in the cell before each run. Temperature was kept constant at 25 ± 0.1 ºC in all experiments.

Britton-Robinson buffer 0.1 mol L^-1 (boric acid, phosphoric acid and acetic acid, 0.1 mol L^-1) was used for aqueous media. All aqueous solutions were prepared with deionized water purified with Milli-Q Ultra-Pure Water System.

Stock solutions of 4-NimMeBr were prepared at a constant concentration of 10^-2 mol L^-1 in Britton-Robinson buffer. The polarographic and cyclic voltammetric working solutions were prepared by diluting the stock solution.

Apparatus

Electrochemical measurements were recorded on electrochemical analizer BAS CV-50W (bioanalytical system) attached to a PC computer with appropriate software (BAS 100W 2.3 for Windows) for total control of the experiments and data acquisition and treatment.

A conventional three-electrode cell was used. Glassy carbon electrode (GCE) of 3 mm diameter (model CHI104, CH Instruments) was used as working electrode for differential pulse voltammetry (DPV), linear sweep voltammetry (LSV) and cyclic voltammetry (CV).

A controlled-growth mercury electrode (CGME) polarographic stand was used with a dropping mercury electrode (DME) as the working electrode for differential pulse polarography (DPP). A platinum wire (BASiMW-1032) as the counter electrode and an Ag/AgCl/NaCl (3 mol L^-1) (BASi MF-2052), as the reference electrode, were used.

A magnetic stirrer was utilized for accumulation of 4-NimMeBr on electrode surface.

Scanning electrochemical microscopy (SECM) measurements were performed with a CHI 900 setup (CH Instrument Inc., USA). For SECM measurements a 10 mm diameter homemade carbon fibber electrode served as SECM tip while GCE modified and unmodified with MWCNT were used as SECM substrate. A platinum wire (BASiMW-1032) as the counter electrode and an Ag/AgCl/NaCl (3 mol L^-1) (BASi MF-2052), as the reference electrode, were used. Ferrocene methanol (FcOH) 1 mmol L^-1 in phosphate buffer solution pH 7.40 was used as a redox mediator.

Procedures

Synthesis of 4-NimMeBr

It was dissolved 1g (4.54 mmol) of 4-NimMeOH²¹ in the minimal volume of pyridine that is possible obtaining a slightly colored solution (yellow very clear). Then 700 µL of SOBr₂ were added, the resultant mixture changed to an orange intense color, then heat to reflux with agitation by 3 h. A yellow precipitate was observed, filtered at vacuum and washed repeatedly with cold acetone to eliminate the excess of pyridine. The product, 40% render, was crystallized in ethanol. The solid re-crystallizes in methanol obtaining white crystals.

The physical and chemical characterization of this compound gave the following results: ¹H NMR (300 MHz, DMSO-d₆): δ 4.9 (s, 3H, NCH₃) 7.2 (s, 2H, CH₂) 9.6 (s, 1H, -C=CH-N-CH₃). Elemental analysis, calc.: C: 27.27%; H: 2.72% and N: 19.09%; found: C: 26.71%; H: 2.88% and N: 18.23%; mp 219-220 ºC.

Preparation of MWCNT suspension and modified GCE

Before each modification, the GCE was cleaned by polishing with 0.3 mm and 0.05 mm alumina, and then was washed with abundant water. The oxidized MWCNT were dispersed at different concentrations (mg mL^-1) with water by sonication for 5 min. The sonication procedure was repeated three times. The immobilization of MWCNT was performed by casting the GCE with 5 µL of the MWCNT dispersion just after sonication. The optimum conditions were obtained drying the dispersion dropped onto the GCE for 15 min at 50 ºC in a stove.

4-NimMeBr adsorption

The modified GCE electrode was immersed in a stirred (250 rpm) supporting buffer solution containing 4-NimMeBr; the accumulation time was variable and no potential was applied during this step.

Voltammetric transduction

It was performed by LSV. The cathodic peak current at around -400 mV, corresponding to the nitro reduction, was used as analytical signal.

Images by SECM

Approach curves and images were obtained following the procedure previously described.²² Specifically, the tip potential was held at 600 mV to produce the oxidation of FcOH (FcOHox), while the substrate potential was held at -100 mV to permit the feedback between the electrodes, since FcOHox generated at the tip is reduced at this potential regenerating the parent FcOH.

Part of the film (no more than 1/3 of the surface) was removed from the glassy carbon modified electrode. Then, an approach curve was conducted on the exposed glassy carbon surface at a tip scan rate of 0.5 mm s^-1. When the tip is far from the substrate and the potencial is applied, FcOHox is generated and the steady-state current i_T, is obtained. When the tip is brought close to the substrate a current i_T is observed due to the formation of FcOH. The tip was stopped when i_T reaches 1.25 times the value of i_T,. According to the theoretical curve that describes the dependence of the i_T with the distance between the tip and the substrate (d), 1.25 times of i_T, corresponds to a d ca. 10 mm, when a 5 mm tip radius is used.²³ After the approach curve, the tip was moved in the x direction to make sure that the tip is over the film and a series of constant height 100 µm × 100 µm area SECM images were recorded at a tip scan rate of 1 mm s^-1. The results are presented in the dimensionless form of i_T, by normalizing the experimental feedback current (i_T) by the steady-state current obtained when the tip was far from the substrate (i_T,), i.e., (I_T = i_T / i_T,).

Results and Discussion

A new synthesized compound, 4-NimMeBr, was electrochemically reduced at mercury electrode in aqueous media 100% Britton-Robinson 0.1 mol L^-1. Only one cathodic peak in all the pH range was detected (Figure 2A).

The peak has a cathodic peak potential, E_p,c of -450 mV at pH 7 and the peak was strongly pH-dependent (Hg electrode). In order to study the pH influence on the nitro reduction we have evaluated the behavior of the peak potential, (Ep) obtained by DPP or DPV at different pH values between 2 and 11. In the Figure 2B, the Ep vs. pH plot shows that the peak potential is pH-dependent shifting to more negative potentials when pH increased. From these results we can observe that the obtained Ep values are very similar with the previously reported²¹ for other 4-nitroimidazole analogue permitting to conclude that the change in the 2-position substitution did not change the reduction of the 4-nitroimidazole moiety. Furthermore from the comparison of the peak potentials between Hg and GCE we can assume that the reduction of nitroimidazole derivative is favoured on Hg.

The cyclic voltammogram (data not shown) of 4-NimMeBr in aqueous media also shows a single peak with not signal in the anodic sweep, which indicates that this peak corresponds to an irreversible process. According to the well-known mechanism of 4-nitroimidazole derivatives ^20,21 we can assume that the observed irreversible peak in all the pH range is due to the four-electron, four-proton reduction of the nitroimidazole group to yield the hydroxylamine derivative according to the following overall reaction:

The voltammetric responses of 9.8×10^-5 mol L^-1 of 4-NimMeBr on a GCE occurs in a similar way to that reported on Hg, i.e., one irreversible peak or wave in aqueous media (Britton-Robinson buffer 0.1 mol L^-1, pH 2) is observed (Figure 3). This Figure shows the comparison of voltammograms of 4-NimMeBr obtained over the same bare polished GCE but with and without 4 min of accumulation time.

After accumulation time is not observed a change in the peak current, however, a little displacement toward more negative potentials in approximately 50 mV is observed. Obviously this result implies that 4-NimMeBr is not adsorbed on the bare GCE.

In order to study the optimal response for the reduction peak of 4-NimMeBr we have tested the modification of the glassy carbon electrode with MWCNT.

Figure 4 shows the voltammograms of 4-NimMeBr obtained at two different electrodes, i.e. bare GCE and MWCNT/GCE prepared using a dispersion of 1 mg mL^-1 MWCNT in water. Using a 1×10^-4 mol L^-1 solution of 4-NimMeBr in 0.1 mol L^-1 Britton-Robinson buffer at pH 2 it was found an important difference in the sensitivity of the current signals, being the current obtained on the MWCNT/GCE higher than the obtained from the bare electrode.

On the other hand the film homogeneity and thickness can be regulated with the concentration of the dispersion. In Figure 5 the MWCNT concentration effect of the MWCNT dispersion on the reduction peak current of 4-NimMeBr is showed.

The results suggested that the film formation is a progressive process that reaches a saturation point near to 4.0 mg mL^-1. On the other hand, more concentrated MWCNT dispersions produce unstable films which increase the relative standard deviation (RSD) of the measurement. Consequently a recommended concentration for the dispersion is 4.0 mg mL^-1 of MWCNT in water for obtaining a better current signal.

The considerable enhancement in the reduction peak current is in part attributed to the strong adsorptive ability of the MWCNT film on GCE. This fact can be corroborated studying the dependence of peak current with the accumulation time of the 4-NimMeBr nitro derivative.

Figure 6 shows LSV of 4-NimMeBr showing the effect of the accumulation time at open-circuit on the reduction peak current of 4-NimMeBr (1.02×10^-5 mol L^-1) using a MWCNT concentration of 4 mg mL^-1. The reduction peak current increases greatly within the first 4 min and then reaches a plateau indicating saturation at the MWCNT electrode. On the other hand the potential peak value did not change at different accumulation times.

Also we have tested if both the type of nanotubes and its functionalization by oxidation affect the response with respect to accumulation time. In this scope we have compared short non-oxidized nanotubes (CNTsnox) with both short (CNTsox) and long (CNTlox) oxidized nanotubes.

The non-oxidized nanotubes obtained the saturated point around 2 min accumulation while the oxidized ones (short and long) about 6 min, showing a significant difference in current intensity (Figure 7). From these experiments is clear that the size of the MWCNT did not affect significantly the current response, however, the oxidized MWCNT produce a modified electrode much more sensitive than the non-oxidized MWCNT.

In order to study with major deep this result we have used SECM to electrochemically map the electrode surface. In Figure 8 we show the SECM images of the electrode surfaces of three different electrodes, i.e., bare GCE, GCE modified with both oxidized and non-oxidized MWCNT.

In the case of oxidized MWCNT it is clear a major cover of the surface by the MWCNT thus explaining the better accumulation ability of the nitroimidazole on this type of MWCNT. On the other hand the higher cover is due to that the functionalization of the MWCNT increases the dispersion of the MWCNT in water. Summarizing, the oxidized MWCNT forms better dispersions than the non-oxidized, producing electrode surface with higher density of MWCNT. Furthermore, the functionalization can create defects on the MWCNT surface exposing more edge plane sites and/or increasing the exposed area of the same. These new highly reactive areas (edge plane when compared with basal plane) could be also responsible for the better accumulation of the nitroimidazole and not only a better dispersion of the CNTs.

Considering the capacity of 4-NimMeBr to be adsorbed in the modified electrode we developed an ASV method to quantify this compound. The first step of the ASV method involves the accumulation of 4-NimMeBr in the MWCNT modified electrodes and the second step involves the stripping of the adsorbed 4-NimMeBr using a linear sweep potential.

Consequently, we have studied the 4-NimMeBr concentration dependence with the peak current. We constructed calibration curves comparing the bare GCE (using LSV technique) with modified electrodes using both large and short oxidized MWCNT (using ASV technique).

From the slope of these curves (Figure 9) it is possible to appreciate considerable differences in the analytical sensibility between bare and modified electrodes. In the case of the bare electrode a sensibility of 0.01 mA per mmol L^-1 was obtained, which was considerable lower than the value of 5.34 and 6.97 mA per mmol L^-1 obtained using short and large oxidized MWCNT, respectively.

The repeatability was evaluated in the same 4-NimMeBr solution by ten consecutive measurements of the peak current in the same electrode. The results show a 2.9% for the variation coefficient, showing good repeatability and stability of the film. On the other hand if the experiments were carried out using accumulation time of 6 min, concentration of the CNTlox dispersion of 4 mg mL^-1, pH 2.0 we obtained detection and quantification limits of 4.41×10^-6 mol L^-1 and 6.21×10^-6 mol L^-1, respectively. The CNTsox showed detection and quantification limits of 8.07×10^-6 mol L^-1 and 11.36×10^-6 mol L^-1. According to the above results the best conditions for the ASV developed method were obtained with oxidized nanotubes obtaining an increased sensibility of about 1000 times compared with the bare electrode.

Conclusions

The electrochemical reduction of 4-NimMeBr in aqueous medium, on carbon electrodes (bare GCE or modified GCE) occurs via one irreversible 4-electron 4-proton wave in a similar way that on mercury electrodes. In spite of no changes in the mechanism was observed considerable differences in peak current when changing from bare to modified electrodes are observed.

The 4-NimMeBr shows highly effective accumulation on modified electrodes with oxidized MWCNT resulting in a significant improvement in sensitivity allowing analytical applications as ASV.

The use of SECM permitted to map the electrode surface thus differentiating a different coverage grade depending if oxidized or non-oxidized MWCNT were used. The oxidized MWCNT formed better dispersions than the non-oxidized, producing electrode surface with higher density of MWCNT. On the other hand the size of the MWCNT did not affect significantly the analytical response of nitroimidazole derivative.

Acknowledgments

The authors are grateful to FONDECYT (Grant No. 1090120) for support of this work.

Submitted: November 15, 2010

Published online: March 3, 2011

1. Lund, H. In Organic Electrochemistry; Lund, H.; Hammerich, O., eds.; 4^th ed., Marcel Dekker Inc., NY, 2001, ch.9, p.379.
2. Riché, F.; du Molinet, A.; Sèpe, S.; Riou, L.; Fagret, D.; Vidal, M.; Bioorg. Med. Chem. Lett. 2001,11,71.
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11. Bartlett, P. N.; Ghoneim, E.; El-Hefnawy, G.; El-Hallag, I.; Talanta 2005,66,869.
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18. Luo, L.-q.; Zou, X.-l.; Ding, Y.-p.; Wu, Q.-s.; Sens. Actuators, B 2008,135,61.
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21. Yañez, C.; Pezoa, J.; Rodríguez, M.; Núñez-Vergara, L. J.; Squella, J. A.; J. Electrochem. Soc. 2005,152,J46.
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*

e-mail:

asquella@ciq.uchile.cl

Publication Dates

Publication in this collection
22 July 2011
Date of issue
July 2011

History

Received
15 Nov 2010
Accepted
03 Mar 2011

This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

[1] 1. Lund, H. In Organic Electrochemistry; Lund, H.; Hammerich, O., eds.; 4^th ed., Marcel Dekker Inc., NY, 2001, ch.9, p.379.

[2] 2. Riché, F.; du Molinet, A.; Sèpe, S.; Riou, L.; Fagret, D.; Vidal, M.; Bioorg. Med. Chem. Lett. 2001,11,71.

[3] 3. Edwards, D. I.; J. Antimicrob. Chemother. 1993,31,9.

[4] 4. Kim, P.; Zhang, L.; Manjunatha, U.; Singh, R.; Patel, S.; Jiricek, J.; Keller, T.; Boshoff , H.; Barry, C.; Dowd, C.; J. Med. Chem. 2009,52,1317.

[5] 5. Valdez, C.; Tripp, J.; Miyamoto, Y.; Kalisiak, J.; Hruz, P.; Andersen, Y.; Brown, S.; Kangas, K.; Arzu, L.; Davids, B.; Gillin, F.; Upcroft, J.; Upcroft, P.; Fokin, V.; Smith, D.; Sharpless, K.; Eckmann, L.; J. Med. Chem. 2009,52,4038.

[6] 6. Kim, P.; Kang, S.; Boshoff, H.; Jiricek, J.; Collins, M.; Singh, R.; Manjunatha, U.; Niyomrattanakit, P.; Zhang, L.; Goodwin, M.; Dick, T.; Keller, T.; Dowd, C.; Barry, C.; J. Med. Chem 2009,52,1329.

[7] 7. Edwards, D. I.; Biochem. Pharmacol. 1986,35,53.

[8] 8. Squella, J. A.; Bollo, S.; Núñez-Vergara, L. J.; Curr. Org. Chem. 2005,9,565.

[9] 9. Squella, J.A.; Campero, A.; Maraver, J.; Carbajo, J.; Electrochim. Acta 2006,52,511.

[10] 10. Bollo, S.; Núñez-Vergara, L. J.; Bontá, M.; Chauviere, G.; Périé, J.; Squella, J. A.; J. Electroanal. Chem. 2001,511,46.

[11] 11. Bartlett, P. N.; Ghoneim, E.; El-Hefnawy, G.; El-Hallag, I.; Talanta 2005,66,869.

[12] 12. El-Sayed, G. O.; Yasin, S. A.; El Badawy, A. A.; Arabian Journal of Chemistry 2010,3,167.

[13] 13. Wang, J.; Electroanalysis 2005,17,7.

[14] 14. Banks, C. E.; Davies, T. J.; Wildgoose, G. G.; Compton, R. G.; Chem. Commun. 2005,7,829.

[15] 15. Cui, H. F.; Ye, J.-S.; Zhang,W.-D.; Wang, J.; Sheu, F.-S.; J. Electroanal. Chem. 2005,577,295.

[16] 16. Yang, S.; Zeng, X.; Liu, X.; Wei, W.; Luo, S.; Liu, Y.; Liu. Y.; J. Electroanal.Chem. 2010,639,181.

[17] 17. Wang, J.; Samo, P.; Hocevar, B.; Ogorevc, B.; Electrochem. Commun. 2004,6,176.

[18] 18. Luo, L.-q.; Zou, X.-l.; Ding, Y.-p.; Wu, Q.-s.; Sens. Actuators, B 2008,135,61.

[19] 19. Li, Y.-P.; Cao, H.-B.; Liu, C.-M.; Yi, Z.; J. Hazard. Mater. 2007,148,158.

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Adsorptive stripping voltammetric determination of nitroimidazole derivative on multiwalled carbon nanotube modified electrodes: influence of size and functionalization of nanotubes

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